CS249276B1 - A method of hardening a flat glass, in particular a glass thickness of less than 3.5 mm, by heating it to a temperature of at least 50 ° C higher than the dilatometric transformation temperature of the glass and subsequent quenching with air at a mouth pressure of over 10 kPa, performed in two stages with different cooling intensity: 2nd stage, ie cooling to lower temperatures, when glass can already be handled, is carried out with a heat transfer coefficient of 150 to 200 W / (m2.K), the shortest usable time of cooling prvního 'being determined based on the knowledge of glass thickness d and coefficient of heat transfer cC in the first stage of cooling according to equations: r - Google Patents

Abstract

The solution concerns a single-path device for examining kidney function and bladder filling in young children, preferably infants. The detection system consists of at least two thin scintillators, mostly based on sodium iodide activated by thallium - NaI(Tl), which are in optical contact with the photocathode of a large-area photomultiplier. The collimating system consists of at least two absorption segments, which form a collimation slit, which is repeatedly moved from one extreme position to the other extreme position perpendicular to the spine of the examined child above his kidneys during the measurement.

Description

BACKGROUND OF THE INVENTION The present invention relates to a profilographic detection system for a single-racial scanning device for examining kidney function by isotopic nephrography and bladder filling in small children, particularly infants.

Isotopic nephrography is a method that allows the function of each kidney to be examined separately. The most commonly used radiopharmaceutical is iodine 131 - J labeled hippuran - sodium salt of orthoiodohippuric acid, which is selectively excreted from the blood by the kidneys by 20% glomerular filtration and 80% by tubular secretion into the urine.

Also suitable for assessing glomerular filtration is technetium ^{9 9m} Tc labeled diethaltriaminepentaacetic acid - DTPA or ethylenediaminotetraacetic acid - EDTA. The elimination phase in this case is slower. Two-channel renography kits with two broadly collimated sointillation detectors and recording the frequency of pulses on paper, tape, or digital evaluation kit are used in the nuclear medicine departments to track the patient's renal passage time.

Scintillation cameras can be used for definitive examination of renal function, which can be used to display the distribution of radiopharmaceuticals simultaneously in both human kidneys, at selected time intervals - that is, sequential gammagraphic examination of the kidneys.

Both of these methods, which are suitable for the examination of adult patients, encounter several basic deficiencies and difficulties when it comes to the examination of small children and infants. For collimated detector examinations, it is particularly difficult to align the field of view of the detectors above the child's kidneys and maintain the same kidney and detector configuration throughout the examination. The kidneys of children and the distance between them are small and therefore a small change in configuration is sufficient to significantly distort the course of the renophragic curves, to jump the registered pulse rate, or by detecting gamma radiation emitted from both kidneys.

In addition to maintaining the same kidney configuration and detection system, scintillation imaging examinations of young children encounter other shortcomings. Radiopharmaceuticals with relatively high activity should be administered so that imaging when the radiopharmaceutical passes through the kidneys is well evaluated. The applied activity is two orders of magnitude higher than when examined by widely collimated detectors. The resulting positional resolution of the cameras is usually not enough for young children to obtain a good image of the distribution of the radiopharmaceutical in the kidneys, images of both kidneys and bladder overlap and make evaluation difficult.

If iodine-131 hippurane-labeled iodine-131 is used in camera tubular filtration of kidneys, approximately 185 kBq per kg of baby's weight, i.e. 0.55 to 1.0 MBq, for a baby weighing 3 to 5.5 kg, should be applied and the radiation load of the child is relatively high.

The radiation load of infants can be reduced by more than an order of magnitude if the same activity of iodine 125 - • “J-labeled hippurane is applied instead of iodine. The iodine 125 radionuclide disintegrates by capturing K without emitting beta radiation and emits soft gamma radiation with an energy of 35 keV, with a proportion of 7% for decay and X radiation with an average energy of about 28 keV with a proportion of 136% for decay.

In young children, the absorption of gamma and X photons with the indicated energies in the kidney and in the tissues between the kidneys and detectors is relatively low, and therefore the iodine emitter 125 may be used, preferably with a small radiation load on the baby. To detect soft gamma and X radiation, special detectors with low absorption of gamma and X photons in the window should be used. A few millimeters of a sensitive layer of thallium activated sodium iodide - NaJ (Tl) scintillator is sufficient for complete absorption of low-energy gamma and X radiation. Such detectors can be easily collimated and effectively shielded. The use of scintillation cameras for gamma photon energies below 60 keV is inappropriate for principle reasons.

The difficulty in aligning the field of vision above the kidneys with frequency variations due to failure to maintain the same configuration between the kidneys and detectors and with high radiation load is eliminated by the profilographic detection system for the single-track scanning device of the invention. It is an object of the invention that the profilographic detection system consists of a scintillation probe with a large-area photomultiplier, to which at least two thalliumine-activated sodium iodide scintillators having a thickness of 1 to 2 mm are attached to the photocathode. at least two absorbent segments, wherein the collimating slit formed by the absorbent segments is in the direction of the child's spine.

The type of scintillation unit, the effective diameter of the photomultiplier, the diameter of the sensitive volume of the scintillator, and the distance between them, ensure satisfactory sensitivity of the profilographic detection system. For infants, a width of 60 to 100 mm and two thallium-activated sodium iodide scintillators with a diameter of 40 to 50 mm or three thallium-activated sodium iodide scintillators with a diameter of 25 mm are suitable.

Satisfactory sensitivity homogeneity in the field of view of the profilographic system is ensured by the choice of scintillator center distances at smaller scintillator sizes, or by absorbing pads, if the entire length of the photomultiplier photocathode is delimited by the collimator, covered with a sensitive scintillator layer.

For low-energy gamma and X-radionuclide radiation, iodine 125 - ¹² µl is sufficient to fully absorb photons in undesirable directions of a brass septum of a thickness of the order of tenths of a millimeter and a collimating septum height of 30 to 50 mm. For gamma radiation of 140 keV technetium ^ ^m Tc, the same applies to bulkheads made of lead sheet metal.

The collimation system consists of a four-baffle arrangement that provides good positional resolution in the direction of movement of the profilographic detection system at high sensitivity. The spacing between the absorbent segments provides a desired positional resolution of less than 10 mm. Optimization of the positional resolution and sensitivity of the detection system according to the dimensions of the examined child is done by changing the distance of the outer absorption segments, balancing the sensitivity of the sensitivity of the detection system along the collimation slit is done by absorption inserts and the scan field width is adjusted by sliding switch contacts.

An embodiment of a profilographic detection system according to the invention is shown in the attached drawing. Giant. 1 shows a top view of a scintillation detection unit with a collimation system, FIG. 2 shows a cross-section of a detection unit perpendicular to the surface of the absorbent segments. The detection system consists of two thin scintillators 2 ^and Z based ^on thallium-activated sodium iodide which is in optical contact with the photocathode of photomultiplier 2 »which is located light tight cover for the scintillation detection unit £. Collimating system 2 ^e 3 consists of two outer segments 6 and the absorbent from the absorbent ^and the two inner segments 2 ^and 2 · The arrow indicates the direction of movement profilografického detection system.

The profiling detection system is moved along the guide frame by the electromechanical unit repeatedly from one end position to the other end position under the deck chair, on which the examined child lies on the back with the body axis perpendicular to the direction of movement of the detection system. The couch sheet, which is made of organic material, is approximately 5 mm from the front of the collimation system 2, the path length of the detection system is adjustable by sliding switches and is selected so that both kidneys are captured with reserve.

As the field of view of the collimated detection system captures sequentially first the tissues outside the first kidney, then the first kidney, the tissues between the kidneys, the second kidney, and the tissues outside the second kidney, we receive a signal pulse frequency corresponding to the radiopharmaceutical activity detected by the field of view.

In normal kidney function, which effectively captures the radiopharmaceutical by the kidneys, we receive a pair of peaks that are more or less well separated depending on how far the kidneys are apart and what the radiopharmaceutical concentration is at the time of scanning in each ice249276 vine and surrounding tissues. By varying the area limited by these peaks and the background and peak shapes, it can be assessed whether both kidneys capture the same amount of radiopharmaceutical and whether the capture and excretion of the radiopharmaceutical into the bladder is normal or what disturbances are involved.

Depending on the speed of the detection system and the width of the field being scanned, we get one pair of peaks in a few tens of seconds. In a 10-minute examination, it is possible to obtain a sufficient number of pairs of notation peaks from which to evaluate the renal function. In the later stages, about two to five minutes after radiopharmaceutical administration, bladder filling occurs in normal renal and ureteral function. Due to the greater distance from the detectors and the higher absorption of gamma and X radiation emitted from the bladder space, the resulting sensitivity to radiation emitted from the bladder is substantially lower.

As activity increases in the bladder and decreases in the kidneys, the ratio of the number of pulses captured in the forage above the kidneys and the peak above the bladder between them decreases. By varying this ratio and the symmetric or asymmetric course of the resulting curve, it is easy to assess whether the urine outflow from both kidneys is continuous or whether it is a one-sided or two-sided urinary outflow.

A profilographic detection system for a single-track scanner can work with conventional single-channel evaluation apparatuses in conjunction with a recorder, but since symmetrical peaks cannot be expected in patients, and because the renal distribution of the radiopharmaceutical varies over time, areas under these peaks and body background, which is tedious and inaccurate in analog recording. To quantify the results, it is therefore preferable to use counter-digital notation of counted pulses at suitably selected time intervals. It is particularly advantageous to connect the described detection system to a multichannel analyzer operating in histogram mode.

Simultaneously manufactured analyzers allow optimization of sampling time with respect to measured frequencies, undistorted recording by selecting the appropriate scale after data acquisition, smoothing of curves and easy and fast quantification of the number of pulses under the measured peaks. All multi-channel analyzers with a 1,000-channel range and a histogram module with a time-of-second sampling time are suitable for the single-track detection system. With such an evaluation system, examinations can be evaluated directly from the screen and recorded on paper only for special cases using an x-y recorder.

It is also attractive for many workplaces to record the measurement results on a tape or punch on a paper tape and evaluate the results using automatic computers.

In addition to the basic improvement in the existing renal function examination, that is, the elimination of defective examinations when the detectors are inaccurately positioned over the kidneys in renographic kits, or a significant reduction in radiation exposure to small children when using cameras. advantages. Compared to dual-channel kits, the difficulty of adjusting and maintaining the same sensitivity of both routes corresponds to operating times. Since scintillation occurs in two or three scintillators, they are scanned by the same photomultiplier, there will be no potential reduction in the photomultiplier, pulse amplifier, etc., in proportion to the heights of the two peaks and their contents according to which the evaluation is performed.

In combination with hippurane-labeled iodine 125, the screening procedure can be considered to be screening even in young children, even if retesting or a large number of examinations are performed. Improved reliability, undistorted data, ease of evaluation of both kidney function by direct comparison of peaks registered side by side, and the ability to read quantitative data directly from the screen are parameters that are highly desirable for screening clinical examinations.

Claims (1)

Profilographic detection system for a single-racial scanning device, characterized in that it consists of a large-area photomultiplier (3), to whose photocathode at least two thin scintillators (1, 2), usually based on thallium activated sodium iodide, are connected in optical contact. 1 to 2 mm, wherein a collimation system (5) consisting of at least two absorption segments (6, 7) is placed above the scintillators (1, 2), the collimation slit formed by these absorption segments (6, 7) being in the direction of the child's spine.